MICROELECTRONICS

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CHAPTER 1
MICROELECTRONICS
LEARNING OBJECTIVES
Learning objectives are stated at the beginning of each topic. These learning objectives serve as a
preview of the information you are expected to learn in the topic. The comprehensive check questions are
based on the objectives. By successfully completing the OCC-ECC, you indicate that you have met the
objectives and have learned the information. The learning objectives are listed below.
Upon completion of this topic, you will be able to:
1. Outline the progress made in the history of microelectronics.
2. Describe the evolution of microelectronics from point-to-point wiring through high element
density state-of-the-art microelectronics.
3. List the advantages and disadvantages of point-to-point wiring and high element density state-ofthe-art microelectronics.
4. Identify printed circuit boards, diodes, transistors, and the various types of integrated circuits.
Describe the fabrication techniques of these components.
5. Define the terminology used in microelectronic technology including the following terms used
by the Naval Systems Commands:
a. microelectronics
b. microcircuit
c. microcircuit module
d. miniature electronics
e. system packaging
f.
levels of packaging (0 to IV)
g. modular assemblies
h. cordwood modules
i.
micromodules
6. Describe typical packaging levels presently used for microelectronic systems.
7. Describe typical interconnections used in microelectronic systems.
8. Describe environmental considerations for microelectronics.
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INTRODUCTION
In NEETS, Module 6, Introduction to Electronic Emission, Tubes, and Power Supplies, you learned
that Thomas Edison's discovery of thermionic emission opened the door to electronic technology.
Progress was slow in the beginning, but each year brought new and more amazing discoveries. The
development of vacuum tubes soon led to the simple radio. Then came more complex systems of
communications. Modern systems now allow us to communicate with other parts of the world via
satellite. Data is now collected from space by probes without the presence of man because of
microelectronic technology.
Sophisticated control systems allow us to operate equipment by remote control in hazardous
situations, such as the handling of radioactive materials. We can remotely pilot aircraft from takeoff to
landing. We can make course corrections to spacecraft millions of miles from Earth. Space flight,
computers, and even video games would not be possible except for the advances made in
microelectronics.
The most significant step in modern electronics was the development of the transistor by Bell
Laboratories in 1948. This development was to solid-state electronics what the Edison Effect was to the
vacuum tube. The solid-state diode and the transistor opened the door to microelectronics.
MICROELECTRONICS is defined as that area of technology associated with and applied to the
realization of electronic systems made of extremely small electronic parts or elements. As discussed in
topic 2 of NEETS, Module 7, Introduction to Solid-State Devices and Power Supplies, the term
microelectronics is normally associated with integrated circuits (IC). Microelectronics is often thought to
include only integrated circuits. However, many other types of circuits also fall into the microelectronics
category. These will be discussed in greater detail under solid-state devices later in this topic.
During World War II, the need to reduce the size, weight, and power of military electronic systems
became important because of the increased use of these systems. As systems became more complex, their
size, weight, and power requirements rapidly increased. The increases finally reached a point that was
unacceptable, especially in aircraft and for infantry personnel who carried equipment in combat. These
unacceptable factors were the driving force in the development of smaller, lighter, and more efficient
electronic circuit components. Such requirements continue to be important factors in the development of
new systems, both for military and commercial markets. Military electronic systems, for example,
continue to become more highly developed as their capability, reliability, and maintainability is increased.
Progress in the development of military systems and steady advances in technology point to an everincreasing need for increased technical knowledge of microelectronics in your Navy job.
Q1. What problems were evident about military electronic systems during World War II?
Q2. What discovery opened the door to solid-state electronics?
Q3. What is microelectronics?
EVOLUTION OF MICROELECTRONICS
The earliest electronic circuits were fairly simple. They were composed of a few tubes, transformers,
resistors, capacitors, and wiring. As more was learned by designers, they began to increase both the size
and complexity of circuits. Component limitations were soon identified as this technology developed.
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VACUUM-TUBE EQUIPMENT
Vacuum tubes were found to have several built-in problems. Although the tubes were lightweight,
associated components and chassis were quite heavy. It was not uncommon for such chassis to weigh 40
to 50 pounds. In addition, the tubes generated a lot of heat, required a warm-up time from 1 to 2 minutes,
and required hefty power supply voltages of 300 volts dc and more.
No two tubes of the same type were exactly alike in output characteristics. Therefore, designers were
required to produce circuits that could work with any tube of a particular type. This meant that additional
components were often required to tune the circuit to the output characteristics required for the tube used.
Figure 1-1 shows a typical vacuum-tube chassis. The actual size of the transformer is approximately
4 × 4 × 3 inches. Capacitors are approximately 1 × 3 inches. The components in the figure are very large
when compared to modern microelectronics.
Figure 1-1.—Typical vacuum tube circuit.
A circuit could be designed either as a complete system or as a functional part of a larger system. In
complex systems, such as radar, many separate circuits were needed to accomplish the desired tasks.
Multiple-function tubes, such as dual diodes, dual triodes, tetrodes, and others helped considerably to
reduce the size of circuits. However, weight, heat, and power consumption continued to be problems that
plagued designers.
Another major problem with vacuum-tube circuits was the method of wiring components referred to
as POINT-TO-POINT WIRING. Figure 1-2 is an excellent example of point-to-point wiring. Not only
did this wiring look like a rat's nest, but it often caused unwanted interactions between components. For
example, it was not at all unusual to have inductive or capacitive effects between wires. Also, point-topoint wiring posed a safety hazard when troubleshooting was performed on energized circuits because of
exposed wiring and test points. Point-to-point wiring was usually repaired with general purpose test
equipment and common hand tools.
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Figure 1-2.—Point-to-point wiring.
Vacuum-tube circuits proved to be reliable under many conditions. Still, the drawbacks of large size,
heavy weight, and significant power consumption made them undesirable in most situations. For
example, computer systems using tubes were extremely large and difficult to maintain. ENIAC, a
completely electronic computer built in 1945, contained 18,000 tubes. It often required a full day just to
locate and replace faulty tubes.
In some applications, we are still limited to vacuum tubes. Cathode-ray tubes used in radar,
television, and oscilloscopes do not, as yet, have solid-state counterparts.
One concept that eased the technician's job was that of MODULAR PACKAGING. Instead of
building a system on one large chassis, it was built of MODULES or blocks. Each module performed a
necessary function of the system. Modules could easily be removed and replaced during troubleshooting
and repair. For instance, a faulty power supply could be exchanged with a good one to keep the system
operational. The faulty unit could then be repaired while out of the system. This is an example of how the
module concept improved the efficiency of electronic systems. Even with these advantages, vacuum tube
modules still had faults. Tubes and point-to-point wiring were still used and excessive size, weight, and
power consumption remained as problems to be overcome.
Vacuum tubes were the basis for electronic technology for many years and some are still with us.
Still, emphasis in vacuum-tube technology is rapidly becoming a thing of the past. The emphasis of
technology is in the field of microelectronics.
Q4. What discovery proved to be the foundation for the development of the vacuum tube?
Q5. Name the components which greatly increase the weight of vacuum-tube circuitry.
Q6. What are the disadvantages of point-to-point wiring?
Q7. What is a major advantage of modular construction?
Q8. When designing vacuum-tube circuits, what characteristics of tubes must be taken into
consideration?
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SOLID-STATE DEVICES
Now would be a good time for you to review the first few pages of NEETS, Module 7, Introduction
to Solid-State Devices and Power Supplies, as a refresher for solid-state devices.
The transition from vacuum tubes to solid-state devices took place rapidly. As new types of
transistors and diodes were created, they were adapted to circuits. The reductions in size, weight, and
power use were impressive. Circuits that earlier weighed as much as 50 pounds were reduced in weight to
just a few ounces by replacing bulky components with the much lighter solid-state devices.
The earliest solid-state circuits still relied on point-to-point wiring which caused many of the
disadvantages mentioned earlier. A metal chassis, similar to the type used with tubes, was required to
provide physical support for the components. The solid-state chassis was still considerably smaller and
lighter than the older, tube chassis. Still greater improvements in component mounting methods were yet
to come.
One of the most significant developments in circuit packaging has been the PRINTED CIRCUIT
BOARD (pcb), as shown in figure 1-3. The pcb is usually an epoxy board on which the circuit leads have
been added by the PHOTOETCHING process. This process is similar to photography in that copper-clad
boards are exposed to controlled light in the desired circuit pattern and then etched to remove the
unwanted copper. This process leaves copper strips (LANDS) that are used to connect the components. In
general, printed circuit boards eliminate both the heavy, metal chassis and the point-to-point wiring.
Figure 1-3.—Printed circuit board (pcb).
Although printed circuit boards represent a major improvement over tube technology, they are not
without fault. For example, the number of components on each board is limited by the sizes and shapes of
components. Also, while vacuum tubes are easily removed for testing or replacement, pcb components
are soldered into place and are not as easily removed.
Normally, each pcb contains a single circuit or a subassembly of a system. All printed circuit boards
within the system are routinely interconnected through CABLING HARNESSES (groups of wiring or
ribbons of wiring). You may be confronted with problems in faulty harness connections that affect system
reliability. Such problems are often caused by wiring errors, because of the large numbers of wires in a
harness, and by damage to those wires and connectors.
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Another mounting form that has been used to increase the number of components in a given space is
the CORDWOOD MODULE, shown in figure 1-4. You can see that the components are placed
perpendicular to the end plates. The components are packed very closely together, appearing to be stacked
like cordwood for a fireplace. The end plates are usually small printed circuit boards, but may be
insulators and solid wire, as shown in the figure. Cordwood modules may or may not be
ENCAPSULATED (totally imbedded in solid material) but in either case they are difficult to repair.
Figure 1-4.—Cordwood module.
Q9. List the major advantages of printed circuit boards.
Q10. What is the major disadvantage of printed circuit boards?
Q11. The ability to place more components in a given space is an advantage of the _______.
INTEGRATED CIRCUITS
Many advertisements for electronic equipment refer to integrated circuits or solid-state technology.
You know the meaning of the term solid-state, but what is an INTEGRATED CIRCUIT? The accepted
Navy definition for an integrated circuit is that it consists of elements inseparably associated and formed
on or within a single SUBSTRATE (mounting surface). In other words, the circuit components and all
interconnections are formed as a unit. You will be concerned with three types of integrated circuits:
MONOLITHIC, FILM, and HYBRID.
MONOLITHIC INTEGRATED CIRCUITS are those that are formed completely within a
semiconductor substrate. These integrated circuits are commonly referred to as SILICON CHIPS.
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FILM INTEGRATED CIRCUITS are broken down into two categories, THIN FILM and THICK
FILM. Film components are made of either conductive or nonconductive material that is deposited in
desired patterns on a ceramic or glass substrate. Film can only be used as passive circuit components,
such as resistors and capacitors. Transistors and/or diodes are added to the substrate to complete the
circuit. Differences in thin and thick film will be discussed later in this topic.
HYBRID INTEGRATED CIRCUITS combine two or more integrated circuit types or combine one
or more integrated circuit types and DISCRETE (separate) components. Figure 1-5 is an example of a
hybrid integrated circuit consisting of silicon chips and film circuitry. The two small squares are chips
and the irregularly shaped gray areas are film components.
Figure 1-5.—Hybrid integrated circuit.
STATE-OF-THE-ART MICROELECTRONICS.
Microelectronic technology today includes thin film, thick film, hybrid, and integrated circuits and
combinations of these. Such circuits are applied in DIGITAL, SWITCHING, and LINEAR (analog)
circuits. Because of the current trend of producing a number of circuits on a single chip, you may look for
further increases in the packaging density of electronic circuits. At the same time you may expect a
reduction in the size, weight, and number of connections in individual systems. Improvements in
reliability and system capability are also to be expected.
Thus, even as existing capabilities are being improved, new areas of microelectronic use are being
explored. To predict where all this use of technology will lead is impossible. However, as the demand for
increasingly effective electronic systems continues, improvements will continue to be made in state-ofthe-art microelectronics to meet the demands.
LARGE-SCALE INTEGRATION (lsi) and VERY LARGE-SCALE INTEGRATION (vlsi) are the
results of improvements in microelectronics production technology. Figure 1-6 is representative of lsi. As
shown in the figure, the entire SUBSTRATE WAFER (slice of semiconductor or insulator material) is
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used instead of one that has been separated into individual circuits. In lsi and vlsi, a variety of circuits can
be implanted on a wafer resulting in further size and weight reduction. ICs in modern computers, such as
home computers, may contain the entire memory and processing circuits on a single substrate.
Figure 1-6.—Large-scale integration device (lsi).
Large-scale integration is generally applied to integrated circuits consisting of from 1,000 to 2,000
logic gates or from 1,000 to 64,000 bits of memory. A logic gate, as you should recall from NEETS,
Module 13, Introduction to Number Systems, Boolean Algebra, and Logic Circuits, is an electronic
switching network consisting of combinations of transistors, diodes, and resistors. Very large-scale
integration is used in integrated circuits containing over 2,000 logic gates or greater than 64,000 bits of
memory.
Q12. Define integrated circuit.
Q13. What are the three major types of integrated circuits?
Q14. How do monolithic ICs differ from film ICs?
Q15. What is a hybrid IC?
Q16. How many logic gates could be contained in lsi?
FABRICATION OF MICROELECTRONIC DEVICES
The purpose of this section is to give you a simplified overview of the manufacture of
microelectronic devices. The process is far more complex than will be described here. Still, you will be
able to see that microelectronics is not magic, but a highly developed technology.
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Development of a microelectronic device begins with a demand from industry or as the result of
research. A device that is needed by industry may be a simple diode network or a complex circuit
consisting of thousands of components. No matter how complex the device, the basic steps of production
are similar. Each type of device requires circuit design, component arrangement, preparation of a
substrate, and the depositing of proper materials on the substrate.
The first consideration in the development of a new device is to determine what the device is to
accomplish. Once this has been decided, engineers can design the device. During the design phase, the
engineers will determine the numbers and types of components and the interconnections, needed to
complete the planned circuit.
COMPONENT ARRANGEMENT
Planning the component arrangement for a microelectronic device is a very critical phase of
production. Care must be taken to ensure the most efficient use of space available. With simple devices,
this can be accomplished by hand. In other words, the engineers can prepare drawings of component
placement. However, a computer is used to prepare the layout for complex devices. The computer is able
to store the characteristics of thousands of components and can provide a printout of the most efficient
component placement. Component placement is then transferred to extremely large drawings. During this
step, care is taken to maintain the patterns as they will appear on the substrate. Figure 1-7 shows a fairly
simple IC MASK PATTERN. If this pattern were being prepared for production, it would be drawn
several hundred times the size shown and then photographed. The photo would then be reduced in size
until it was the actual desired size. At that time, the pattern would be used to produce several hundred
patterns that would be used on one substrate. Figure 1-8 illustrates how the patterns would be distributed
to act as a WAFER MASK for manufacturing.
Figure 1-7.—IC mask pattern.
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Figure 1-8.—Wafer mask distribution.
A wafer mask is a device used to deposit materials on a substrate. It allows material to be deposited
in certain areas, but not in others. By changing the pattern of the mask, we can change the component
arrangement of the circuit. Several different masks may be used to produce a simple microelectronic
device. When used in proper sequence, conductor, semiconductor, or insulator materials may be applied
to the substrate to form transistors, resistors, capacitors, and interconnecting leads.
SUBSTRATE PRODUCTION
As was mentioned earlier in this topic, microelectronic devices are produced on a substrate. This
substrate will be of either insulator or semiconductor material, depending on the type of device. Film and
hybrid ICs are normally constructed on a glass or ceramic substrate. Ceramic is usually the preferred
material because of its durability.
Substrates used in monolithic ICs are of semiconductor material, usually silicon. In this type of IC,
the substrate can be an active part of the IC. Glass or ceramic substrates are used only to provide support
for the components.
Semiconductor substrates are produced by ARTIFICIALLY GROWING cylindrical CRYSTALS of
pure silicon or germanium. Crystals are "grown" on a SEED CRYSTAL from molten material by slowly
lifting and cooling the material repeatedly. This process takes place under rigidly controlled atmospheric
and temperature conditions.
Figure 1-9 shows a typical CRYSTAL FURNACE. The seed crystal is lowered until it comes in
contact with the molten material-silicon in this case. It is then rotated and raised very slowly. The seed
crystal is at a lower temperature than the molten material. When the molten material is in contact with the
seed, it solidifies around the seed as the seed is lifted. This process continues until the grown crystal is of
the desired length. A typical crystal is about 2 inches in diameter and 10 to 12 inches long. Larger
diameter crystals can be grown to meet the needs of the industry. The purity of the material is strictly
controlled to maintain specific semiconductor properties. Depending on the need, n or p impurities are
added to produce the desired characteristics. Several other methods of growing crystals exist, but the
basic concept of crystal production is the same.
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Figure 1-9.—Crystal furnace.
The cylinder of semiconductor material that is grown is sliced into thicknesses of .010 to .020 inch in
the first step of preparation, as shown in figure 1-10. These wafers are ground and polished to remove any
irregularities and to provide the smoothest surface possible. Although both sides are polished, only the
side that will receive the components must have a perfect finish.
Figure 1-10.—Silicon crystal and wafers.
Q17. What are the basic steps in manufacturing an IC?
Q18. Computer-aided layout is used to prepare _______ devices.
Q19. What purpose do masks serve?
Q20. What type of substrates are used for film and hybrid ICs?
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Q21. Describe the preparation of a silicon substrate.
FABRICATION OF IC DEVICES
Fabrication of monolithic ICs is the most complex aspect of microelectronic devices we will discuss.
Therefore, in this introductory module, we will try to simplify this process as much as possible. Even
though the discussion is very basic, the intent is still to increase your appreciation of the progress in
microelectronics. You should, as a result of this discussion, come to realize that advances in
manufacturing techniques are so rapid that staying abreast of them is extremely difficult.
Monolithic Fabrication.
Two types of monolithic fabrication will be discussed. These are the DIFFUSION METHOD and the
EPITAXIAL METHOD.
DIFFUSION METHOD.—The DIFFUSION process begins with the highly polished silicon wafer
being placed in an oven (figure 1-11). The oven contains a concentration impurity made up of impurity
atoms which yield the desired electrical characteristics. The concentration of impurity atoms is diffused
into the wafer and is controlled by controlling the temperature of the oven and the time that the silicon
wafer is allowed to remain in the oven. This is called DOPING. When the wafer has been uniformly
doped, the fabrication of semiconductor devices may begin. Several hundred circuits are produced
simultaneously on the wafer.
Figure 1-11.—Wafers in a diffusion oven.
The steps in the fabrication process described here, and illustrated in figure 1-12, would produce an
npn, planar-diffused transistor. But, with slight variations, the technique may also be applied to the
production of a complete circuit, including diodes, resistors, and capacitors. The steps are performed in
the following order:
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Figure 1-12.—Planar-diffused transistor.
1. An oxide coating is thermally grown over the n-type silicon starting material.
2. By means of the photolithographic process, a window is opened through the oxide layer. This is
done through the use of masks, as discussed earlier.
3. The base of the transistor is formed by placing the wafer in a diffusion furnace containing a ptype impurity, such as boron. By controlling the temperature of the oven and the length of time
that the wafer is in the oven, you can control the amount of boron diffused through the window
(the boron will actually spread slightly beyond the window opening). A new oxide layer is then
allowed to form over the area exposed by the window.
4. A new window, using a different mask much smaller than the first, is opened through the new
oxide layer.
5. An n-type impurity, such as phosphorous, is diffused through the new window to form the
emitter portion of the transistor. Again, the diffused material will spread slightly beyond the
window opening. Still another oxide layer is then allowed to form over the window.
6. By means of precision-masking techniques, very small windows (about 0.005 inch in diameter)
are opened in both the base and emitter regions of the transistor to provide access for electrical
currents.
7. Aluminum is then deposited in these windows and alloyed to form the leads of the transistor or
the IC.
(Note that the pn junctions are covered throughout the fabrication process by an oxide layer that
prevents contamination.)
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EPITAXIAL METHOD.—The EPITAXIAL process involves depositing a very thin layer of
silicon to form a uniformly doped crystalline region (epitaxial layer) on the substrate. Components are
produced by diffusing appropriate materials into the epitaxial layer in the same way as the planardiffusion method. When planar-diffusion and epitaxial techniques are combined, the component
characteristics are improved because of the uniformity of doping in the epitaxial layer. A cross section of
a typical planar-epitaxial transistor is shown in figure 1-13. Note that the component parts do not
penetrate the substrate as they did in the planar-diffused transistor.
Figure 1-13.—Planar-epitaxial transistor.
ISOLATION.—Because of the closeness of components in ICs, ISOLATION from each other
becomes a very important factor. Isolation is the prevention of unwanted interaction or leakage between
components. This leakage could cause improper operation of a circuit.
Techniques are being developed to improve isolation. The most prominent is the use of silicon oxide,
which is an excellent insulator. Some manufacturers are experimenting with single-crystal silicon grown
on an insulating substrate. Other processes are also used which are far too complex to go into here. With
progress in isolation techniques, the reliability and efficiency of ICs will increase rapidly.
Thin Film
Thin film is the term used to describe a technique for depositing passive circuit elements on an
insulating substrate with coating to a thickness of 0.0001 centimeter. Many methods of thin-film
deposition exist, but two of the most widely used are VACUUM EVAPORATION and CATHODE
SPUTTERING.
VACUUM EVAPORATION.—Vacuum evaporation is a method used to deposit many types of
materials in a highly evacuated chamber in which the material is heated by electricity, as shown in figure
1-14. The material is radiated in straight lines in all directions from the source and is shadowed by any
objects in its path.
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Figure 1-14.—Vacuum evaporation oven.
The wafers, with appropriate masks (figure 1-15), are placed above and at some distance from the
material being evaporated. When the process is completed, the vacuum is released and the masks are
removed from the wafers. This process leaves a thin, uniform film of the deposition material on all parts
of the wafers exposed by the open portions of the mask. This process is also used to deposit
interconnections (leads) between components of an IC.
Figure 1-15.—Evaporation mask.
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The vacuum evaporation technique is most suitable for deposition of highly reactive materials, such
as aluminum, that are difficult to work with in air. The method is clean and allows a better contact
between the layer of deposited material and the surface upon which it has been deposited. In addition,
because evaporation beams travel in straight lines, very precise patterns may be produced.
CATHODE-SPUTTERING.—A typical cathode-sputtering system is illustrated in figure 1-16.
This process is also performed in a vacuum. A potential of 2 to 5 kilovolts is applied between the anode
and cathode (source material). This produces a GLOW DISCHARGE in the space between the electrodes.
The rate at which atoms are SPUTTERED off the source material depends on the number of ions that
strike it and the number of atoms ejected for each ion bombardment. The ejected atoms are deposited
uniformly over all objects within the chamber. When the sputtering cycle is completed, the vacuum in the
chamber is released and the wafers are removed. The masks are then removed from the wafers, leaving a
deposit that forms the passive elements of the circuit, as shown in figure 1-17.
Figure 1-16.—Cathode-sputtering system.
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Figure 1-17.—Cathode-sputtering mask.
Finely polished glass, glazed ceramic, and oxidized silicon have been used as substrate materials for
thin films. A number of materials, including nichrome, a compound of silicon oxide and chromium
cermets, tantalum, and titanium, have been used for thin-film resistors. Nichrome is the most widely used.
The process for producing thin-film capacitors involves deposition of a bottom electrode, a
dielectric, and finally a top electrode. The most commonly used dielectric materials are silicon monoxide
and silicon dioxide.
Thick Film
Thick films are produced by screening patterns of conducting and insulating materials on ceramic
substrates. A thick film is a film of material with a thickness that is at least 10 times greater than the mean
free path of an electron in that material, or approximately 0.001 centimeter. The technique is used to
produce only passive elements, such as resistors and capacitors.
PROCEDURES.—One procedure used in fabricating a thick film is to produce a series of stencils
called SCREENS. The screens are placed on the substrate and appropriate conducting or insulating
materials are wiped across the screen. Once the conducting or insulating material has been applied, the
screens are removed and the formulations are fired at temperatures above 600 degrees Celsius. This
process forms alloys that are permanently bonded to the insulating substrate. To a limited extent, the
characteristics of the film can be controlled by the firing temperature and length of firing time.
RESISTORS.—Thick-film resistance values can be held to a tolerance of ±10 percent. Closer
tolerances are obtained by trimming each resistor after fabrication. Hundreds of different cermet
formulations are used to produce a wide range of component parameters. For example, the material used
for a 10-ohm-per-square resistor is quite different from that used for a 100-kilohm-per-square resistor.
CAPACITORS AND RESISTOR-CAPACITOR NETWORKS.—Capacitors are formed by a
sequence of screenings and firings. Capacitors in this case consist of a bottom plate, intraconnections, a
dielectric, and a top plate. For resistor-capacitor networks, the next step would be to deposit the resistor
material through the screen. The final step is screening and firing of a glass enclosure to seal the unit.
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Hybrid Microcircuit
A hybrid microcircuit is one that is fabricated by combining two or more circuit types, such as film
and semiconductor circuits, or a combination of one or more circuit types and discrete elements. The
primary advantage of hybrid microcircuits is design flexibility; that is, hybrid microcircuits can be
designed to provide wide use in specialized applications, such as low-volume and high-frequency circuits.
Several elements and circuits are available for hybrid applications. These include discrete
components that are electrically and mechanically compatible with ICs. Such components may be used to
perform functions that are supplementary to those of ICs. They can be handled, tested, and assembled
with essentially the same technology and tools. A hybrid IC showing an enlarged chip is shown in figure
1-18.
Figure 1-18.—Hybrid IC showing an enlarged chip.
Complete circuits are available in the form of UNCASED CHIPS (UNENCAPSULATED IC DICE).
These chips are usually identical to those sold as part of the manufacturer's regular production line. They
must be properly packaged and connected by the user if a high-quality final assembly is to be obtained.
The circuits are usually sealed in a package to protect them from mechanical and environmental stresses.
One-mil (0.001-inch), gold-wire leads are connected to the appropriate pins which are brought out of the
package to allow external connections.
Q22. Name the two types of monolithic IC construction discussed.
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Q23. How do the two types of monolithic IC construction differ?
Q24. What is isolation?
Q25. What methods are used to deposit thin-film components on a substrate?
Q26. How are thick-film components produced?
Q27. What is a hybrid IC?
Q28. What is the primary advantage of hybrid circuits?
PACKAGING TECHNIQUES
Once the IC has been produced, it requires a housing that will protect it from damage. This damage
could result from moisture, dirt, heat, radiation, or other sources. The housing protects the device and aids
in its handling and connection into the system in which the IC is used. The three most common types of
packages are the modified TRANSISTOR-OUTLINE (TO) PACKAGE, the FLAT PACK, and the
DUAL INLINE PACKAGE (DIP).
Transitor-Outline Package
Transistor-Outline Package. The transistor-outline (TO) package was developed from early
experience with transistors. It was a reliable package that only required increasing the number of leads to
make it useful for ICs. Leads normally number between 2 and 12, with 10 being the most common for IC
applications. Figure 1-19 is an exploded view of a TO-5 package. Once the IC has been attached to the
header, bonding wires are used to attach the IC to the leads. The cover provides the necessary protection
for the device. Figure 1-20 is an enlarged photo of an actual TO-5 with the cover removed. You can easily
see that the handling of an IC without packaging would be difficult for a technician.
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Figure 1-19.—Exploded TO-5.
Figure 1-20.—TO-5 package.
The modified TO-5 package (figure 1-21) can be either plugged into [view (A)] or embedded in
[view (B)] a board. The embedding method is preferred. Whether the package is plugged in or embedded,
the interconnection area of the package leads must have sufficient clearance on both sides of the board.
The plug-in method does not provide sufficient clearance between pads to route additional circuitry.
When the packages are embedded, sufficient space exists between the pads [because of the increased
diameter of the interconnection pattern, shown at the right in view (B)] for additional conductors.
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Figure 1-21A.—TO-5 mounting PLUG-IN MOUNTING
Figure 1-21B.—TO-5 mounting EMBEDDED CAN(LEADS PLUGGED IN)
Flat Pack
Many types of IC flat packs are being produced in various sizes and materials. These packages are
available in square, rectangular, oval, and circular configurations with 10 to 60 external leads. They may
be
made of metal, ceramic, epoxy, glass, or combinations of those materials. Only the ceramic flat pack will
be discussed here. It is representative of all flat packs with respect to general package requirements (see
figure 1-22).
1-21
Figure 1-22.—Enlarged flat pack exploded view.
After the external leads are sealed to the mounting base, the rectangular area on the inside bottom of
the base is treated with metal slurry to provide a surface suitable for bonding the monolithic die to the
base. The lead and the metalized area in the bottom of the package are plated with gold. The die is then
attached by gold-silicon bonding.
The die-bonding step is followed by bonding gold or aluminum wires between the bonding islands
on the IC die and on the inner portions of the package leads. Next, a glass-soldered preformed frame is
placed on top of the mounting base. One surface of the ceramic cover is coated with Pyroceram glass, and
the cover is placed on top of the mounting base. The entire assembly is placed in an oven at 450 degrees
Celsius. This causes the glass solder and Pyroceram to fuse and seal the cover to the mounting base. A
ceramic flat pack is shown in figure 1-23. It has been opened so that you can see the chip and bonding
wires.
Figure 1-23.—Typical flat pack.
1-22
Dual Inline Package
The dual inline package (DIP) was designed primarily to overcome the difficulties associated with
handling and inserting packages into mounting boards. DIPs are easily inserted by hand or machine and
require no spreaders, spacers, insulators, or lead-forming tools. Standard hand tools and soldering irons
can be used to field-service the devices. Plastic DIPs are finding wide use in commercial applications, and
a number of military systems are incorporating ceramic DIPS.
The progressive stages in the assembly of a ceramic DIP are illustrated in figure 1-24, views (A)
through (E). The integrated-circuit die is sandwiched between the two ceramic elements, as shown in
view (A). The element on the left of view (A) is the bottom half of the sandwich and will hold the
integrated-circuit die. The ceramic section on the right is the top of the sandwich. The large well in view
(B) protects the IC die from mechanical stress during sealing operations. Each of the ceramic elements is
coated with glass which has a low melting temperature for subsequent joining and sealing. View (B)
shows the Kovar lead frame stamped and bent into its final shape. The excess material is intended to
preserve pin alignment. The holes at each end are for the keying jig used in the final sealing operation.
The lower half of the ceramic package is inserted into the lead frame shown in view (C). The die is
mounted in the well and leads are attached. The top ceramic elements are bonded to the bottom element
shown in view (D) and the excess material is removed from the package. View (E) is the final product.
Figure 1-24.—DIP packaging steps.
Ceramic DIPs are processed individually while plastic DIPs are processed in quantities of two or
more (in chain fashion). After processing, the packages are sawed apart. The plastic package also uses a
Kovar lead frame, but the leads are not bent until the package is completed. Because molded plastic is
1-23
used to encapsulate the IC die, no void will exist between the cover and die, as is the case with ceramic
packaging.
At present, ceramic DIPs are the most common of the two package types to be found in Navy
microelectronic systems. Figure 1-25 shows a DIP which has been opened.
Figure 1-25.—Dual inline package (DIP).
RECENT DEVELOPMENTS IN PACKAGING
Considerable effort has been devoted to eliminating the fine wires used to connect ICs to Kovar
leads. The omission of these wires reduces the cost of integrated circuits by eliminating the costs
associated with the bonding process. Further, omission of the wires improves reliability by eliminating a
common cause of circuit failure.
A promising packaging technique is the face-down (FLIP-CHIP) mounting method by which
conductive patterns are evaporated inside the package before the die is attached. These patterns connect
the external leads to bonding pads on the inside surface of the die. The pads are then bonded to
appropriate pedestals on the package that correspond to those of the bonding pads on the die (figure 1-26).
Figure 1-26.—Flip-chip package.
The BEAM-LEAD technique is a process developed to batch-fabricate (fabricate many at once)
semiconductor circuit elements and integrated circuits with electrodes extended beyond the edges of the
1-24
wafer, as shown in figure 1-27. This type of structure imposes no electrical difficulty, and parasitic
capacitance (under 0.05 picofarad per lead) is equivalent to that of a wire-bonded and brazed-chip
assembly. In addition, the electrodes may be tapered to allow for lower inductance, impedance matching,
and better heat conductance. The beam-lead technique is easily accomplished and does not have the
disadvantages of chip brazing and wire bonding. The feasibility of this technique has been demonstrated
in a variety of digital, linear, and thin-film circuits.
Figure 1-27.—Beam-lead technique.
Another advance in packaging is that of increasing the size of DIPs. General purpose DIPs have from
4 to 16 pins. Because of lsi and vlsi, manufacturers are producing DIPs with up to 64 pins. Although size
is increased considerably, all the advantages of the DIP are retained. DIPs are normally designed to a
particular specification set by the user.
Q29. What is the purpose of the IC package?
Q30. What are the three most common types of packages?
Q31. What two methods of manufacture are being used to eliminate bonding wires?
EQUIVALENT CIRCUITS
At the beginning of this topic, we discussed many applications of microelectronics. You should
understand that these applications cover all areas of modern electronics technology. Microelectronic ICs
are produced that can be used in many of these varying circuit applications to satisfy the needs of modern
technology. This section will introduce you to some of these applications and will show you some
EQUIVALENT CIRCUIT comparisons of discrete components and integrated circuits.
J-K FLIP-FLOP AND IC SIZES
Integrated circuits can be produced that combine all the elements of a complete electronic circuit.
This can be done with either a single chip of silicon or a single chip of silicon in combination with film
components. The importance of this new production method in the evolution of microelectronics can be
demonstrated by comparing a conventional J-K flip-flop circuit incorporating solid-state discrete devices
and the same type of circuit employing integrated circuitry. (A J-K flip-flop is a circuit used primarily in
computers.)
1-25
You should recall from NEETS, Module 13, Introduction to Number Systems, Boolean Algebra, and
Logic Circuits, that a basic flip-flop is a device having two stable states and two input terminals (or types
of input signals), each of which corresponds to one of the two states. The flip-flop remains in one state
until caused to change to the other state by application of an input voltage pulse.
A J-K flip-flop differs from the basic flip-flop because it has a third input terminal. A clock pulse, or
trigger, is usually applied to this input to ensure proper timing in the circuit. An input signal must occur at
the same time as the clock pulse to change the state of the flip-flop. The conventional J-K flip-flop circuit
in figure 1-28 requires approximately 40 discrete components, 200 connections, and 300 processing
operations. Each of these 300 operations (seals and connections) represents a possible source of failure. If
all the elements of this circuit are integrated into one chip of silicon, the number of connections drops to
approximately 14. This is because all circuit elements are intraconnected inside the package and the 300
processing operations are reduced to approximately 30. Figure 1-29 represents a size comparison of a
discrete J-K circuit and an integrated circuit of the same type.
Figure 1-28.—Schematic diagram of a J-K flip-flop.
1-26
Figure 1-29.—J-K flip-flop discrete component and an IC.
IC PACKAGE LEAD IDENTIFICATION (NUMBERING)
When you look at an IC package you should notice that the IC could be connected incorrectly into a
circuit. Such improper replacement of a component would likely result in damage to the equipment. For
this reason, each IC has a REFERENCE MARK to align the component for placement. The dual inline
package (both plastic and ceramic) and the flat pack have a notch, dot, or impression on the package.
When the package is viewed from the top, pin 1 will be the first pin in the counterclockwise direction next
to the reference mark. Pin 1 may also be marked directly by a hole or notch or by a tab on it (in this case
pin 1 is the counting reference). When the package is viewed from the top, all other pins are numbered
consecutively in a counterclockwise direction from pin 1, as shown in figure 1-30, views (A) and (B).
1-27
Figure 1-30A.—DIP and flat-pack lead numbering. DIP
Figure 1-30B.—DIP and flat-pack lead numbering. Flat-Pack
The TO-5 can has a tab for the reference mark. When numbering the leads, you must view the TO-5
can from the bottom. Pin 1 will be the first pin in a clockwise direction from the tab. All other pins will be
numbered consecutively in a clockwise direction from pin 1, as shown in figure 1-31.
1-28
Figure 1-31.—Lead numbering for a TO-5.
IC IDENTIFICATION
As mentioned earlier, integrated circuits are designed and manufactured for hundreds of different
uses. Logic circuits, clock circuits, amplifiers, television games, transmitters, receivers, and musical
instruments are just a few of these applications.
In schematic drawings, ICs are usually represented by one of the schematic symbols shown in figure
1-32. The IC is identified according to its use by the numbers printed on or near the symbol. That series
of numbers and letters is also stamped on the case of the device and can be used along with the data sheet,
as shown in the data sheet in figure 1-33, by circuit designers and maintenance personnel. This data sheet
is provided by the manufacturer. It provides a schematic diagram and describes the type of device, its
electrical characteristics, and typical applications. The data sheet may also show the pin configurations
with all pins labeled. If the pin configurations are not shown, there may be a schematic diagram showing
pin functions. Some data sheets give both pin configurations and schematic diagrams, as shown in figure
1-34. This figure illustrates a manufacturer's data sheet with all of the pin functions shown.
Figure 1-32.—Some schematic symbols for ICs.
1-29
Figure 1-33.—Manufacturer's Data Sheet.
1-30
Figure 1-34.—Manufacturer's Data Sheet.
1-31
Q32. On DIP and flat-pack ICs viewed from the top, pin 1 is located on which side of the reference
mark?
Q33. DIP and flat-pack pins are numbered consecutively in what direction?
Q34. DIP and flat-pack pins are numbered consecutively in what direction?
Q35. Viewed from the bottom, TO-5 pins are counted in what direction?
Q36. The numbers and letters on ICs and schematics serve what purpose?
MICROELECTRONIC SYSTEM DESIGN CONCEPTS
You should understand the terminology used in microelectronics to become an effective and
knowledgeable technician. You should be familiar with packaging concepts from a maintenance
standpoint and be able to recognize the different types of assemblies. You should also know the electrical
and environmental factors that can affect microelectronic circuits. In the next section of this topic we will
define and discuss each of these areas.
TERMINOLOGY
As in any special electronics field, microelectronics terms and definitions are used to clarify
communications. This is done so that everyone involved in microelectronics work has the same
knowledge of the field. You can imagine how much trouble you would have remembering 10 or more
different names and definitions for a resistor. If standardization didn't exist for the new terminology, you
would have far more trouble understanding microelectronics. To standardize terminology in
microelectronics, the Navy has adopted several definitions with which you should become familiar. These
definitions will be presented in this section.
Microelectronics
Microelectronics is that area of electronics technology associated with electronics systems built from
extremely small electronic parts or elements. Most of today's computers, weapons systems, navigation
systems, communications systems, and radar systems make extensive use of microelectronics technology.
Microcircuit
A microcircuit is not what the old-time technician would recognize as an electronic circuit. The oldtimer would no longer see the familiar discrete parts (individual resistors, capacitors, inductors,
transistors, and so forth). Microelectronic circuits, as discussed earlier, are complete circuits mounted on a
substrate (integrated circuit). The process of fabricating microelectronic circuits is essentially one of
building discrete component characteristics either into or onto a single substrate. This is far different from
soldering resistors, capacitors, transistors, inductors, and other discrete components into place with wires
and lugs. The component characteristics built into microcircuits are referred to as ELEMENTS rather than
discrete components. Microcircuits have a high number of these elements per substrate compared to a
circuit with discrete components of the same relative size. As a matter of fact, microelectronic circuits
often contain thousands of times the number of discrete components. The term HIGH EQUIVALENT
CIRCUIT DENSITY is a description of this element-to-discrete part relationship. For example, suppose
you have a circuit with 1,000 discrete components mounted on a chassis which is 8 × 10 × 2 inches. The
equivalent circuit in microelectronics might be built into or onto a single substrate which is only 3/8 × 1 ×
1/4 inch. The 1,000 elements of the microcircuit would be very close to each other (high density) by
1-32
comparison to the distance between discrete components mounted on the large chassis. The elements
within the substrate are interconnected on the single substrate itself to perform an electronic function. A
microcircuit does not have any discrete components mounted on it as do printed circuit boards, circuit
card assemblies, and modules composed exclusively of discrete component parts.
Microcircuit Module
Microcircuits may be used in combination with discrete components. An assembly of microcircuits
or a combination of microcircuits and discrete conventional electronic components that performs one or
more distinct functions is a microcircuit module. The module is constructed as an independently
packaged, replaceable unit. Examples of microcircuit modules are printed circuit boards and circuit card
assemblies. Figure 1-35 is a photograph of a typical microcircuit module.
Figure 1-35.—Microcircuit module.
Miniature Electronics
Miniature electronics includes miniature electronic components and packages. Some examples are
printed circuit boards, printed wiring boards, circuit card assemblies, and modules composed exclusively
of discrete electronic parts and components (excluding microelectronic packages) mounted on boards,
assemblies, or modules. MOTHER BOARDS, large printed circuit boards with plug-in modules, are
considered miniature electronics. Cordwood modules also fall into this category. Miniature motors,
synchros, switches, relays, timers, and so forth, are also classified as miniature electronics.
Recall that microelectronic components contain integrated circuits. Miniature electronics contain
discrete elements or parts. You will notice that printed circuit boards and circuit card assemblies are
mentioned in more than one definition. To identify the class (microminiature or miniature) of the unit,
you must first determine the types of components used.
Q37. Standardized terms improve what action between individuals?
Q38. Microcircuit refers to any component containing what types of elements?
Q39. Components made up exclusively of discrete elements are classified as what type of electronics?
SYSTEM PACKAGING
When a new electronics system is developed, several areas of planning require special attention. An
area of great concern is that of ensuring that the system performs properly. The designer must take into
1-33
account all environmental and electrical factors that may affect the system. This includes temperature,
humidity, vibration, and electrical interference. The design factor that has the greatest impact on you, as
the technician, is the MAINTAINABILITY of the system. The designer must take into account how well
you will be able to locate problems, identify the faulty components, and make the necessary repairs. If a
system cannot be maintained easily, then it is not an efficient system. PACKAGING, the method of
enclosing and mounting components, is of primary importance in system maintainability.
Levels of Packaging
For the benefit of the technician, system packaging is usually broken down to five levels (0 to IV).
These levels are shown in figure 1-36.
Figure 1-36.—Packaging levels.
LEVEL 0.—Level 0 packaging identifies nonrepairable parts, such as integrated circuits, transistors,
resistors, and so forth. This is the lowest level at which you can perform maintenance. You are limited to
simply replacing the faulty element or part. Depending on the type of part, repair might be as simple as
plugging in a new relay. If the faulty part is an IC, special training and equipment will be required to
accomplish the repair. This will be discussed in topic 2.
LEVEL I.—This level is normally associated with small modules or submodules that are attached to
circuit cards or mother boards. The analog-to-digital (A/D) converter module is a device that converts a
signal that is a function of a continuous variable (like a sine wave) into a representative number sequence
in digital form. The A/D converter in figure 1-37 is a typical Level I component. At this level of
1-34
maintenance you can replace the faulty module with a good one. The faulty module can then be repaired
at a later time or discarded. This concept significantly reduces the time equipment is inoperable.
Figure 1-37.—Printed circuit board (pcb).
LEVEL II.—Level II packaging is composed of large printed circuit boards and/or cards (mother
boards). Typical units of this level are shown in figures 1-37 and 1-38. In figure 1-38 the card measures
15 × 5.25 inches. The large dual inline packages (DIPs) are 2.25 inches x 0.75 inch. Other DIPs on the
pcb are much smaller. Interconnections are shown between DIPs. You should also be able to locate a few
discrete components. Repair consists of removing the faulty DIP or discrete component from the pcb and
replacing it with a new part. Then the pcb is placed back into service. The removed part may be a level 0
or I part and would be handled as described in those sections. In some cases, the entire pcb should be
replaced.
Figure 1-38.—Printed circuit board (pcb).
1-35
LEVEL III.—Drawers or pull-out chassis are level III units, as shown in figure 1-36. These are
designed for accessibility and ease of maintenance. Normally, circuit cards associated with a particular
subsystem will be grouped together in a drawer. This not only makes for an orderly arrangement of
subsystems but also eliminates many long wiring harnesses. Defective cards are removed from such
drawers and defective components are repaired as described in level II.
LEVEL IV.—Level IV is the highest level of packaging. It includes the cabinets, racks, and wiring
harnesses necessary to interconnect all of the other levels. Other pieces of equipment of the same system
classified as level IV, such as radar antennas, are broken down into levels 0 to III in the same manner.
During component troubleshooting procedures, you progress from level IV to III to II and on to level
0 where you identify the faulty component. As you become more familiar with a system, you should be
able to go right to the drawer or module causing the problem.
Q40. Resistors, capacitors, transistors, and the like, are what level of packaging?
Q41. Modules or submodules attached to a mother board are what packaging level?
Q42. What is the packaging level of a pcb?
INTERCONNECTIONS IN PRINTED CIRCUIT BOARDS
As electronic systems become more complex, interconnections between components also becomes
more complex. As more components are added to a given space, the requirements for interconnections
become extremely complicated. The selection of conductor materials, insulator materials, and component
physical size can greatly affect the performance of the circuit. Poor choices of these materials can
contribute to poor signals, circuit noise, and unwanted electrical interaction between components. The
three most common methods of interconnection are the conventional pcb, the multilayer pcb, and the
modular assembly. Each of these will be discussed in the following sections.
Conventional Printed Circuit Board
Printed circuit boards were discussed earlier in topic 1. You should recall that a conventional pcb
consists of glass-epoxy insulating base on which the interconnecting pattern has been etched. The board
may be single- or double-sided, depending on the number of components mounted on it. Figures 1-37 and
1-38 are examples of conventional printed circuit boards.
Multilayer Printed Circuit Board.
The multilayer printed circuit board is emerging as the solution is interconnection problems
associated with high-density packaging. Multilayer boards are used to:
•
reduce weight
•
conserve space in interconnecting circuit modules
•
eliminate costly and complicated wiring harnesses
•
provide shielding for a large number of conductors
•
provide uniformity in conductor impedance for high-speed switching systems
1-36
•
allow greater wiring density on boards
Figure 1-39 illustrates how individual boards are mated to form the multilayer unit. Although all
multilayer boards are similarly constructed, various methods can be used to interconnect the circuitry
from layer to layer. Three proven processes are the clearance-hole, plated-through hole, and layer buildup methods.
Figure 1-39.—Multilayer pcb.
CLEARANCE-HOLE METHOD.—In the CLEARANCE-HOLE method, a hole is drilled in the
copper island (terminating end) of the appropriate conductor on the top layer. This provides access to a
conductor on the second layer as shown by hole A in figure 1-40. The clearance hole is filled with solder
to complete the connection. Usually, the hole is drilled through the entire assembly at the connection site.
This small hole is necessary for the SOLDER-FLOW PROCESS used with this interconnection method.
Figure 1-40.—Clearance-hole interconnection.
1-37
Conductors located several layers below the top are connected by using a STEPPED-DOWN HOLE
PROCESS. Before assembly of a three-level board, a clearance hole is drilled down to the first layer to be
interconnected. The first layer to be interconnected is predrilled with a hole smaller than those drilled in
layers 1 and 2; succeeding layers to be connected have progressively smaller clearance holes. After
assembly, the exposed portion of the conductors are interconnected by filling the stepped-down holes
with solder, as shown by hole B in figure 1-40. The larger the number of interconnections required at one
point, the larger must be the diameter of the clearance holes on the top layer. Large clearance holes on the
top layer allow less space for components and reduce packaging density.
PLATED-THROUGH-HOLE METHOD.—The PLATED-THROUGH-HOLE method of
interconnecting conductors is illustrated in figure 1-41. The first step is to temporarily assemble all the
layers into their final form. Holes corresponding to required connections are drilled through the entire
assembly and then the unit is disassembled. The internal walls of those holes to be interconnected are
plated with metal which is 0.001 inch thick. This, in effect, connects the conductor on the board surface
through the hole itself. This process is identical to that used for standard printed circuit boards. The
boards are then reassembled and permanently bonded together with heat and pressure. All the holes are
plated through with metal.
Figure 1-41.—Plated through-hole interconnection.
LAYER BUILD-UP METHOD.—With the LAYER BUILD-UP method, conductors and
insulation layers are alternately deposited on a backing material, as shown in figure 1-42. This method
produces copper interconnections between layers and minimizes the thermal expansion effects of
dissimilar materials. However, reworking the internal connections in built-up layers is usually difficult, if
not impossible.
1-38
Figure 1-42.—Layer build-up technique.
Advantages and Disadvantages of Printed Circuit Boards
Some of the advantages and disadvantages of printed circuit boards were discussed earlier in this
topic. They are strong, lightweight, and eliminate point-to-point wiring. Multilayer printed circuit boards
allow more components per card. Entire circuits or even subsystems may be placed on the same card.
However, these cards do have some drawbacks. For example, all components are wired into place, repair
of cards requires special training and/or special equipment, and some cards cannot be economically
repaired because of their complexity (these are referred to as THROWAWAYS).
MODULAR ASSEMBLIES
The MODULAR-ASSEMBLY (nonrepairable item) approach was devised to achieve ultra-high
density packaging. The evolution of this concept, from discrete components to microelectronics, has
progressed through various stages. These stages began with cordwood assemblies and functional blocks
and led to complete subsystems in a single package. Examples of these configurations are shown in figure
1-43, view (A), view (B), and view (C).
1-39
Figure 1-43A.—Evolution of modular assemblies. CORDWOOD.
Figure 1-43B.—Evolution of modular assemblies. MICROMODULE.
1-40
Figure 1-43C.—Evolution of modular assemblies. INTEGRATED-CIRCUIT.
Cordwood Modules.
The cordwood assembly, shown in view (A) of figure 1-43, was designed and fabricated in various
forms and sizes, depending on user requirements. This design was used to reduce the physical size and
increase the component density and complexity of circuits through the use of discrete devices. However,
the use of the technique was somewhat limited by the size of available discrete components used.
Micromodules
The next generation assembly was the micromodule. Designers tried to achieve maximum density in
this design by using discrete components, thick- and thin-film technologies, and the insulator substrate
principle. The method used in this construction technique allowed for the efficient use of space and also
provided the mechanical strength necessary to withstand shock and vibration.
Semiconductor technology was then improved further with the introduction of the integrated circuit.
The flat-pack IC form, shown in view (C), emphasizes the density and complexity that exists with this
technique. This technology provides the means of reducing the size of circuits. It also allows the reduction
of the size of systems through the advent of the lsi circuits that are now available and vlsi circuits that are
being developed by various IC manufacturers.
Continuation of this trend toward microminiaturization will result in system forms that will require
maintenance personnel to be specially trained in maintenance techniques to perform testing, fault
isolation, and repair of systems containing complex miniature and microminiature circuits.
Q43. What are the three most common methods of interconnections?
Q44. Name the three methods of interconnecting components in multilayer printed circuit boards.
Q45. What is one of the major disadvantages of multilayer printed circuit boards?
Q46. What was the earliest form of micromodule?
1-41
ENVIRONMENTAL CONSIDERATIONS
The environmental requirements of each system design are defined in the PROCUREMENT
SPECIFICATION. Typical environmental requirements for an IC, for example, are shown in table 1-1.
After these system requirements have been established, components, applications, and packaging forms
are considered. This then leads to the most effective system form.
Table 1-1.—Environmental Requirements
Temperature Operating Nonoperating
Humidity
Shock
Vibration
RF Interference
−28º C to +65º
C −62º C to +75º C (MIL-E-16400E)
95 percent plus condensation (MIL-E-16400E)
250 to 600 g (MIL-S-901C)
5 to 15 Hz, 0.060 DA 16 to 25 Hz, 0.040 DA 26 to
33 Hz, 0.020 DA Resonance test in three mutual
perpendicular planes. (MIL-STD-167)
30 Hz to 40 GHz
In the example in table 1-1, the environmental requirements are set forth as MILITARY
STANDARDS for performance. The actual standard for a particular factor is in parentheses. To meet
each of these standards, the equipment or component must perform adequately within the test guidelines.
For example, to pass the shock test, the component must withstand a shock of 250 to 600 Gs (force of
gravity). During vibration testing, the component must withstand vibrations of 5 to 15 cycles per second
for 0.06 day, or about 1 1/2 hours; 16 to 25 cycles for 1 hour; and 26 to 33 cycles for 1/2 hour. Rf
interference between 30 hertz and 40 gigahertz must not affect the performance of the component.
Temperature and humidity factors are self-explanatory.
When selecting the most useful packaging technique, the system designer must consider not only the
environmental and electrical performance requirements of the system, but the maintainability aspects as
well. The system design will, therefore, reflect performance requirements of maintenance and repair
personnel.
ELECTRICAL CONSIDERATIONS
The electrical characteristics of a component can sometimes be adversely affected when it is placed
in a given system. This effect can show up as signal distortion, an improper timing sequence, a frequency
shift, or numerous other types of unwanted interactions. Techniques designed to minimize the effects of
system packaging on component performance are incorporated into system design by planners. These
techniques should not be altered during your maintenance. Several of the techniques used by planners are
discussed in the following sections.
Ground Planes and Shielding.
At packaging levels I and II, COPPER PLANES with voids, where feed-through is required, can be
placed anywhere within the multilayer board. These planes tend to minimize interference between circuits
and from external sources.
At other system levels, CROSS TALK (one signal interfering with another), rf generation within the
system, and external interference are suppressed through the use of various techniques. These techniques
1-42
are shown in figure 1-44. As shown in the figure, rf shielding is used on the mating surfaces of the
package, cabling is shielded, and heat sinks are provided.
Figure 1-44.—Ground planes and shielding.
Interconnection and Intraconnections
To meet the high-frequency characteristics and propagation timing required by present and future
systems, the device package must not have excessive distributed capacitance and/or inductance. This type
of packaging is accomplished in the design of systems using ICs and other microelectronic devices by
using shorter leads internal to the package and by careful spacing of complex circuits on printed circuit
boards. To take advantage of the inherent speed of the integrated circuit, you must keep the signal
propagation time between circuits to a minimum. The signal is delayed approximately 1 nanosecond per
foot, so reducing the distance between circuits as much as possible is necessary. This requires the use of
structures, such as high-density digital systems with an emphasis on large-scale integration, for systems in
the future. Also, maintenance personnel should be especially concerned with the spacing of circuits, lead
dress, and surface cleanliness. These factors affect the performance of high-speed digital and analog
circuits.
Q47. In what publication are environmental requirements for equipment defined?
Q48. In what publication would you find guidelines for performance of military electronic parts?
Q49. Who is responsible for meeting environmental and electrical requirements of a system?
Q50. What methods are used to prevent unwanted component interaction?
1-43
SUMMARY
This topic has presented information on the development and manufacture of microelectronic
devices. The information that follows summarizes the important points of this topic.
VACUUM-TUBE CIRCUITS in most modern military equipment are unacceptable because of
size, weight, and power use.
Discovery of the transistor in 1948 marked the beginning of MICROELECTRONICS.
The PRINTED CIRCUIT BOARD (pcb) reduces weight and eliminates point-to-point wiring.
The INTEGRATED CIRCUITS (IC) consist of elements inseparably associated and formed on or
within a single SUBSTRATE.
ICs are classified as three types: MONOLITHIC, FILM, and HYBRID.
The MONOLITHIC IC, called a chip or die, contains both active and passive elements.
1-44
FILM COMPONENTS are passive elements, either resistors or capacitors.
HYBRID ICs are combinations of monolithic and film or of film and discrete components, or any
combination thereof. They allow flexibility in circuits.
1-45
Rapid development has resulted in increased reliability and availability, reduced cost, and higher
element density.
LARGE-SCALE (lsi) and VERY LARGE-SCALE INTEGRATION (vlsi) allow thousands of
elements in a single chip.
MONOLITHIC ICs are produced by the diffusion or epitaxial methods.
DIFFUSED elements penetrate the substrate, EPITAXIAL do not.
ISOLATION is a production method to prevent unwanted interaction between elements within a
chip.
THIN-FILM ELEMENTS are produced through EVAPORATION or CATHODE
SPUTTERING techniques.
THICK-FILM ELEMENTS are screened onto the substrate.
The most common types of packages for ICs are TO, FLAT PACK, and DUAL INLINE.
1-46
FLIP CHIPS and BEAM-LEAD CHIPS are techniques being developed to eliminate bonding
wires and to improve packaging.
1-47
Large DIPs are being used to package lsi and vlsi. They can be produced with up to 64 pins and are
designed to fulfill a specific need.
Viewed from the tops, DIPS and FLAT-PACK LEADS are numbered counterclockwise from the
reference mark.
Viewed from the bottom, TO-5 LEADS are numbered clockwise from the tab.
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Numbers and letters on schematics and ICs identify the TYPE OF IC.
Knowledge of TERMINOLOGY used in microelectronics and of packaging concepts will aid you
in becoming an effective technician.
STANDARD TERMINOLOGY has been adopted by the Navy to ease communication.
MICROELECTRONICS is that area of technology associated with electronic systems designed
with extremely small parts or elements.
A MICROCIRCUIT is a small circuit which is considered as a single part composed of elements on
or within a single substrate.
A MICROCIRCUIT MODULE is an assembly of microcircuits or a combination of microcircuits
and discrete components packaged as a replaceable unit.
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MINIATURE ELECTRONICS are card assemblies and modules composed exclusively of discrete
electronic components.
SYSTEM PACKAGING refers to the design of a system, taking into account environmental and
electronic characteristics, access, and maintainability.
PACKAGING LEVELS 0 to IV are used to identify assemblies within a system. Packaging levels
are as follows:
LEVEL 0-Nonrepairable parts (resistors, diodes, and so forth.)
LEVEL I -Submodules attached to circuit cards.
LEVEL II -Circuit cards and MOTHER BOARDS.
LEVEL III - Drawers.
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LEVEL IV - Cabinets.
The most common METHODS OF INTERCONNECTION are the conventional pcb, the
multilayer pcb, and modular assemblies.
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Three methods of interconnecting circuitry in multilayer printed circuit boards are the
CLEARANCE-HOLE, the PLATED-THROUGH-HOLE, and LAYER BUILD-UP.
MODULAR ASSEMBLIES were devised to achieve high circuit density.
Modular assemblies have progressed from CORDWOOD MODULES through
MICROMODULES. Micromodules consist of film components and discrete components to integrated
and hybrid circuitry.
ENVIRONMENTAL FACTORS to be considered are temperature, humidity, shock, vibration, and
rf interference.
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ELECTRICAL FACTORS are overcome by using shielding and ground planes and by careful
placement of components.
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ANSWERS TO QUESTIONS Q1. THROUGH Q50.
A1. Size, weight, and power consumption.
A2. The transistor and solid-state diode.
A3. Technology of electronic systems made of extremely small electronic parts or elements.
A4. The Edison Effect.
A5. Transformers, capacitors, and resistors.
A6. "Rat's nest" appearance and unwanted interaction, such as capacitive and inductive effects.
A7. Rapid repair of systems and improved efficiency.
A8. Differences in performance of tubes of the same type.
A9. Eliminate heavy chassis and point-to-point wiring.
A10. Components soldered in place.
A11. Cordwood module.
A12. Elements inseparably associated and formed in or on a single substrate.
A13. Monolithic, film, and hybrid.
A14. Monolithic ICs contain active and passive elements. Film ICs contain only passive elements.
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A15. Combination of monolithic ICs and film components.
A16. 1,000 to 2,000.
A17. Circuit design, component placement, suitable substrate, and depositing proper materials on
substrate.
A18. Complex.
A19. Control patterns of materials on substrates.
A20. Glass or ceramic.
A21. Crystal is sliced into wafers. Then ground and polished to remove any surface defect.
A22. Diffusion; epitaxial growth.
A23. Diffusion penetrates substrate; epitaxial does not.
A24. Electrical separation of elements.
A25. Evaporation and cathode sputtering.
A26. Screening.
A27. Combination of monolithic and film elements.
A28. Circuit flexibility.
A29. Protect the IC from damage; make handling easier.
A30. TO, flat pack, DIP.
A31. Flip-chip, beam lead.
A32. Left.
A33. Counterclockwise.
A34. Reference mark.
A35. Clockwise.
A36. Identify the type of IC.
A37. Communication.
A38. Integrated circuits.
A39. Miniature.
A40. Level 0.
A41. Level I.
A42. Level II.
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A43. Conventional printed circuit boards, multilayer printed circuit boards and modular assemblies.
A44. Clearance hole, plated-through hole, and layer build-up.
A45. Difficulty of repair of internal connections.
A46. Cordwood modules.
A47. Procurement specifications.
A48. Military Standards.
A49. Equipment designers (planners).
A50. Ground planes, shielding, component placement.
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